The next subnet starts at the next boundary. But why are you requiring each department to be in its own subnet?
You should use /24 blocks where possible. If security of some weird sort or physical cable limitations come into play, then do subdivide further, but know that you lose 2 IP addresses for each subnet--you cannot use the 1st and last IP of a block, the subnet and broadcast addresses respectively. So a /27 offers only 30 usable addresses and a /30 only 2, with 50% wastage. You can't use the .0 or .255 of a /24. You can't use the 0, 31, 32, 63, 64, 95, and so on of a /27. A /31 is not possible as it would have no usable IPs.
Using the .25/27 address will work but is identical to .0/27. The mask of 27 1-bits renders the last 5 bits useless, intentionally. That is what network masks do.
You really need to study this up a bit as you can make mistakes that have a negative effect on your network.
The slash notation for network masks specifies the number of one bits in the mask that indicate the network address portion. It sounds like you've got a basic understanding of this. But extending this all the way, for a /27 this means that the last 5 bits (32 - 27) of an address are removed before calculating the subnet address.
Let's say a packet arrives on a router and the destination is 126.96.36.199. If that router has a routing table with an entry 188.8.131.52/27 in it (specifying which of the router's internal gateway addresses to forward the packet to) it can determine that this address belongs to that block like so:
IP: 10001100 00001010 00001010 00011101 (184.108.40.206)
Mask: 11111111 11111111 11111111 11100000 (255.255.255.224 aka /27)
Net: 10001100 00001010 00001010 00000000 (220.127.116.11)
The important thing here is that the resulting network address is simply the destination IP, with any bits in the mask with 0 setting the corresponding bits to 0 in the destination. This results in the network address, as you see, of 18.104.22.168. So this is why for a /27, specifying anything besides an even multiple of 32 in the last octet is meaningless. It is the same for all network address blocks. You do not have to divide a network block into equal sizes, but all must be aligned on a power of 2 boundary, which doesn't just specify the size but also the alignment of the starting network address.
As an example, you could break up a /25 like this:
/27 .0 - .31
/30 .32 - .35
/30 .36 - .39
/29 .40 - .47
/28 .48 - .63
/26 .64 - .127
/25 .128 - .255
It is like a binary tree. If you split an item, it has to be split exactly in half. Then, each half can be left alone or further subdivided exactly in half each time.
This crude ASCII diagram may help a little. Each split divides the remaining space in half. At the bottom, somewhere, there must be two adjacent blocks that are the same size.
| | |
+-+ --+ --/30
| | | |
--+ --+ --/29
| | |
| | --/28
This subnets thing is very important. At one small company I worked for--and I had just left a 6-month stint as a contractor helping an ISP to renumber customer networks--they couldn't figure out why a computer would not work on the network. The address was something like .224 or another likely subnet boundary, or so I was suspicious. When I asked "what are the subnets here?" the CEO snapped at me "that's not the problem! We don't need your help!" So I shut up, but an hour or two later found out that the problem had been... they'd divided their /24 into subnets and the address that they were attempting to use was a network address, which is not valid. This division into subnets made no sense as it was basically a single-room large office with no physical cabling limitations. They should have just used the /24 as is.
These things matter. Unnecessarily dividing into subnets will lose usable IP addresses, and potentially cause confusion.